2. Heterogeneity in Distributed GISs
[Worboys, M., et al., 1991] classified semantic heterogeneity as generic and contextual. The earlier occurs
when different GIS applications are using different generic models of the spatial information. For example
one may use a layer-based approach and a second may use an object-based approach. The contextual
heterogeneity occurs when the semantics of schemes depend upon the local conditions at particular GISs.
For example two spatial databases holding two different objects that have two different meanings, though
they refer to the same real world entity, e.g., agricultural fields in environmental database is different from
that in a cadastral database. [Spaccapietra, S., et al., 1991] listed 4 classes of heterogeneity or conflicts:
semantic conflict, descriptive conflict, data model conflict, and structural conflict. The semantic conflict
occurs in the situation where set of objects from two schemes are representing sets of real world entities
which are related by a set comparison operators other than equality. Descriptive conflict occurs when two
database objects, representing the same real world entities, are described with different sets of properties.
Data model conflict is the situation where two schemes are defined with different data models, e.g.,
relational and object oriented models. The situation where two related objects are represented using
different data structures is called structural conflict. For example a designer represents a component X of
an object O either by creating a new object type X or add it as a property of O.
A relatively similar classification of types of database heterogeneity was presented by [Saltor et al., 1993].
They provided more comprehensive classification of heterogeneity to which we are more inclined. Their
classification has three aspects: syntactic, schematic, and semantic. Descriptive and structural conflicts are
equivalent to schematic heterogeneity, while the data model conflict is equivalent to syntactic conflict.
1. Syntactic: each database may be implemented in a different DBMS with a different data model, e.g.,
relational model Vs object oriented model. Moreover, syntactic heterogeneity is also related to the
geometric representation of geographic objects, e.g., raster and vector representations.
2. Schematic: where objects in one database are considered as properties or metadata in the other, or
object classes of the same real world entity have different hierarchies and descriptors in different
databases.
3. Semantic: a real world entity may have two different meanings in their underlying databases in order to
serve various applications, giving as a consequence semantic conflicts. For example a road network in
a GIS for transportation has different semantics from that in a GIS for topographic mapping.
3. Heterogeneity And Spatial Objects
Geographic object representation in a GIS contains both thematic and geometric information. For most
applications the thematic information of terrain description and analysis are of prime importance. This
means that the querying and processing will be organized and formulated primarily from a thematic
perspective. The structuring and formulation of the analysis of the geometric aspects of the data will be
secondary [Molenaar, M. 1995]. This statement leads to two important conclusions. Firstly, object
identification in a heterogeneous database environment should not rely on its geometric representation.
Secondly, resolving the geometric discrepancies between different GIS has to be solved independently
from the thematic ones.
There are two approaches for geographic object representation in GIS: 1) field approach in which the earth
surface is presented as spatio-temporal continuum; 2) object-structured planar graph approach in which
terrain features are defined by their geometry, shape and position (in addition to thematic descriptors). In
addition to the above three types of heterogeneity, mentioned in section 2, there is also spatial
